Spanish researchers developing rear-side concentrated PV modules for agrivoltaics

<p class="p1"><span class="s1">Researchers at University of Jaén in Spain have demonstrated a semi-transparent crystalline silicon solar photovoltaic module with rear-side optical concentrators for agrivoltaics applications.</span></p><p>A research team at Spain's <a href="https://www.pv-magazine.com/2024/01/31/photovoltaics-for-wastewater-disinfection/" rel="noopener" target="_blank">University of Jaén</a> demonstrated a novel agrivoltaics <a href="https://www.pv-magazine.com/2024/06/11/concentrator-photovoltaic-module-based-on-surface-mount-technology/" rel="noopener" target="_blank">concentrator PV module</a>, featuring rear-side crossed compound parabolic concentrators (CCPC) and crystalline silicon solar cells emulating a bifacial configuration. To suit agricultural applications, it was designed to balance high efficiency and optical transparency with minimal panel shading. </p>
<p>“Our research presents the first semi-transparent photovoltaic (STPV) module that uses rear optical concentrators specifically to enhance the contribution of reflected irradiance, a resource that has traditionally been underutilized in both agrivoltaics and building-integrated photovoltaic systems,” co-corresponding author of the research, Álvaro Valera-Albacete, told <strong>pv magazine.</strong></p>
<p>Unlike earlier STPV designs, the prototype, RearCPVbif, concentrates and redirects albedo light to the rear of bifacial cells for a “substantial increase&#8221; in power generation without compromising optical transparency, according to Valera-Albacete. </p>
<p>“The main motivation was the growing need to reconcile solar energy production with limited land availability,” explained Valera-Albacete, noting that, in agrivoltaics, increasing electrical output “typically comes at the cost of reducing the quality and quantity of light&#8221; that reaches the crops due to shading by the PV modules.</p>
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<p>The researchers fabricated a prototype module and developed a modelling framework for testing. The proposed design integrates low-concentration optical components on the back side, aligned and bonded to small, interspaced crystalline silicon solar cells. The geometric concentration had a targeted transparency factor (TRF) of 60%, which is “adequate for most horticultural crops,” according to the researchers.</p>
<p>To emulate the bifacial cells required for the design, the scientists used two electrically independent monofacial crystalline silicon solar cells. These were placed in 3 × 3 arrays and mounted on an 8 mm thick transparent polymethyl methacrylate (PMMA) substrate. The module was 42.8 mm thick and weighed 0.4767 kg, or 34.15 kg/m². </p>
<p>Tests of optical performance of CCPC power output gain, light quality, average photosynthetic transmittance (APT), average visible transmittance (AVT), and thermal performance were completed. The results showed a bifacial response, with the &#8220;rear side generating more than twice the power of the front, showing clear gains over monofacial and bifacial references,&#8221; according to the research.</p>
<p>The system also provided “good transmission of diffuse light” and visible transmittance of close to 60%. Thermal performance remained stable, with “predicted cell temperatures below 70 C, &#8220;with the insulating capacity &#8220;comparable to that of double-glazing systems,” reported the researchers.</p>
<p>They said that the experimental and numerical results were in “good agreement for light transmission and uniformity,” but they also noted discrepancies in non-uniformity, indicating the need to further refine the model and to perform outdoor testing. </p>
<p>The work is described in &#8220;<a href="https://doi.org/10.1016/j.rineng.2025.108241" rel="noopener" target="_blank">Study on the potential of a novel semi-transparent rear concentrator photovoltaic system for agrivoltaics</a>,&#8221; published in <em>Results in Engineering</em>.</p>
<p>Currently, the researchers are in discussions with private sector organizations to accelerate development and transfer the technology to the market, according to Eduardo F. Fernández, co-corresponding author of the research. </p>
<p>&#8220;<span>This also includes a detailed assessment of the benefits that the technology provides for crop growth, based on an experimental campaign in which different types of crops are investigated,&#8221; said Fernández.</span></p>
<p>In addition, the research team is building on its experience with optics and solar cells by researching <a href="https://www.pv-magazine.com/2025/10/31/photovoltaic-thermoelectric-generators-can-boost-power-beaming-efficiency/">wireless energy transfer</a> applications with high-power photovoltaic receivers and monochromatic laser light sources.</p>
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